Mechanism of interaction of sitamaquine with Leishmania donovani.

OBJECTIVES: This study focuses on the mechanism of interaction of sitamaquine with Leishmania donovani membranes, and its accumulation within the parasites. METHODS: A biomimetic model of the outer layer of a Leishmania plasma membrane was used to examine the interactions of sitamaquine with lipids. The plasma membranes of L. donovani promastigotes were depleted of sterol using cholesterol oxidase, in order to assess the importance of sterols in drug-membrane interactions. Sterols were quantified and sitamaquine susceptibility was assessed using the MTT test. Kinetics of sitamaquine accumulation and efflux were measured under different conditions. RESULTS: Sitamaquine interacts first with phospholipid anionic polar head groups and then with phospholipid acyl chains to insert within biological membranes and accumulates rapidly in the Leishmania cytosol according to a sterol-independent process. The rapid sitamaquine efflux observed was related to an energy-dependent mechanism since the intracellular amount of sitamaquine was enhanced three times in the absence of glucose and the efflux was inhibited in energy-depleted conditions. (1)H NMR analysis of motile lipid showed that sitamaquine did not affect lipid trafficking in Leishmania. CONCLUSIONS: We propose that sitamaquine rapidly accumulates in Leishmania by diffusion along an electrical gradient and is concentrated in the cytosol by an energy- and sterol-independent process. The affinity of sitamaquine for membranes was transitory and an energy-dependent efflux was demonstrated, suggesting the presence of an as yet uncharacterized transporter.

Membrane sterol depletion impairs miltefosine action in wild-type and miltefosine-resistant Leishmania donovani promastigotes.

OBJECTIVES: This study focuses on the importance of sterols in the action of miltefosine (hexadecylphosphocholine, HePC) against Leishmania donovani. METHODS: Plasma membranes of L. donovani promastigotes were depleted of sterol using methyl-beta-cyclodextrin (MCD) and cholesterol oxidase (CH-OX). Sterols were quantified and HePC susceptibility was assessed using the MTT test. A biomimetic model of the outer leaflet of a Leishmania plasma membrane was used to decipher the HePC-lipid interactions. RESULTS: CH-OX, which is known to act more specifically on condensed membranes, therefore at the level of lipid rafts, gave a better extraction yield in HePC-resistant parasites, confirming the more rigid structure of their membranes than those of wild-type parasites. Sterol depletion was responsible for a 40% decrease in HePC susceptibility in both wild-type and HePC-resistant parasites. Sterol repletion of the sterol-depleted parasites restored HePC susceptibility. The biomimetic model of the outer leaflet of a Leishmania plasma membrane confirmed that condensed microdomains were able to incorporate higher quantities of HePC than fluid ones and this result was amplified when the sterol concentration was increased. CONCLUSIONS: Sterol and lipid rafts probably play a significant role as an HePC reservoir providing a constant supply to the previously described transporter. In addition, (1)H NMR experiments suggested that HePC stimulated lipid trafficking in parasites.

Amphotericin B-sterol complex formation and competition with egg phosphatidylcholine: a monolayer study.

The conditions of formation of amphotericin B-cholesterol or -ergosterol complexes in monolayers are investigated by the penetration into a monolayer of egg phosphatidylcholine/sterol of 14C-labelled N-fructosyl-amphotericin B dissolved in the aqueous subphase. An increase of both surface pressure and radioactivity as a function of concentration are observed simultaneously while a 'saturation' effect occurs only for the surface pressure. The experiments are not accurate enough to make conclusions about the number of actually penetrated amphotericin B molecules. Therefore, the existence of an amphotericin B-sterol complex was evidenced from a study of surface pressure area per molecule isotherm. The results indicate that a complex with a 2:1 stoichiometry is formed and that the amphotericin B-ergosterol interaction is larger than the amphotericin B-cholesterol interaction. The complex is dissociated by addition of egg phosphatidylcholine due to a competition between egg phosphatidylcholine and amphotericin B for sterol.

Oligonucleotide delivery by a cationic derivative of the polyene antibiotic amphotericin B. II: study of the interactions of the oligonucleotide/cationic vector complexes with lipid monolayers and lipid unilamellar vesicles.

We report a study of the behavior of oligodeoxyribonucleotide (ODN)/amphotericin B3-(N'-dimethylamino)propylamide (AMA) complexes, in the presence of lipid monolayers and large unilamellar vesicles. This study follows the recent discovery of the capacity of AMA, as a new cationic vector, to enhance ODN cellular uptake and efficacy. It aims at investigating the internalization mode of a nucleic acid by AMA. A first study at the air-water interface of AMA and AMA/ODN by surface pressure measurement shows that only free AMA would adsorb at the air-water interface. Second, in the presence of zwitterionic phospholipid- and sterol-containing mixture, ODN-AMA interactions in solution would be higher than lipid-AMA interactions at the interface. In monolayer or with large unilamellar vesicles, AMA monomers adsorb mainly at the phospholipid interface. These results favor a crossing mechanism through AMA channel formation, despite the size of ODN.

Oligonucleotide delivery by a cationic derivative of the polyene antibiotic amphotericin B. I: interaction oligonucleotide/vector as studied by optical spectroscopy and electron microscopy.

Antisense strategy requires efficient systems for the delivery of oligodeoxyribonucleotides (ODN) into target cells. Cationic amphiphiles have shown good efficiency in vitro and a lot of attention is currently paid to their interaction with nucleic acids. In the present study, this interaction was, for the first time, analysed at the molecular level, taking advantage of the spectroscopic properties of the positively charged chiral polyene molecule amphotericin B 3-dimethylaminopropyl amide (AMA), the efficiency of which, as delivery system, has been demonstrated [Garcia et al., Pharmacol. Ther. (2000), in press]. By UV-visible absorption and circular dichroism (CD) we studied its self-association properties in pure water, saline and RPMI medium. Drastic changes were observed upon ODN addition, stronger in pure water than in media of high ionic strength. At low AMA concentration (<10(-6) M), the strong increase of the CD signal, characteristic of self-association, indicated condensation of AMA on the ODN molecules. At a higher concentration (10(-4) M), and for a nucleic acid negative charge/AMA positive charge ratio higher than 1, spectra were interpreted as a reorganisation of free self-associated AMA species into smaller ones 'decorating' the nucleic acid molecule. Electron microscopy data were interpreted according to this scheme.

Interactions of antileishmanial drugs with monolayers of lipids used in the development of amphotericin B-miltefosine-loaded nanocochleates.

The emergence of strains of Leishmania resistant to existing drugs complicates the treatment of life-threatening visceral leishmaniasis. The development of new lipid formulation (nanocochleates), containing two active drugs: amphotericin B (AmB) and miltefosine (hexadecylphosphocholine, HePC), could increase effectiveness, decrease toxicity and reduce the risk of appearance of resistance. Nanocochleates are cigar-shaped structures of rolled negatively charged lipid bilayers bridged by calcium, prepared from dioleoylphosphatidylserine (DOPS) and cholesterol (Cho) and able to accommodate drugs. To determine the interaction, the orientation and the stability of the amphiphilic drugs in the lipid mixture and the optimal drugs/lipids ratio, the Langmuir film balance and BAM (Brewster angle microscopy) were used. The drugs were mixed with the lipids (DOPS or 9DOPS/1Cho) and spread at the air-water interface. A stability study showed that DOPS maintained HePC at the interface at low molar fraction of HePC; this effect became more marked in the presence of Cho. The fact that HePC can be stably associated with the monolayer at low molar fraction (below 10%) suggests that in the nanocochleates HePC is inserted between the lipid molecules rather than between the bilayers. Phase diagrams and BAM images showed that, even at low pressure, DOPS maintains AmB at low molar fraction (below 10%) in the "erect" rather than the horizontal form at the interface and that the presence of Cho reinforces this effect. These results allowed us to predict the organization and the orientation of these drugs in the nanocochleates and to determine the optimal drugs/lipids ratio.

Alteration of fatty acid and sterol metabolism in miltefosine-resistant Leishmania donovani promastigotes and consequences for drug-membrane interactions.

Miltefosine (hexadecylphosphocholine [HePC]) is the first orally active drug approved for the treatment of visceral leishmaniasis. In order to investigate the biochemical modifications occurring in HePC-resistant (HePC-R) Leishmania donovani promastigotes, taking into account the lipid nature of HePC, we investigated their fatty acid and sterol metabolisms. We found that the content of unsaturated phospholipid alkyl chains was lower in HePC-R parasite plasma membranes than in those of the wild type, suggesting a lower fluidity of HePC-R parasite membranes. We also demonstrated that HePC insertion within an external monolayer was more difficult when the proportion of unsaturated phospholipids decreased, rendering the HePC interaction with the external monolayer of HePC-R parasites more difficult. Furthermore, HePC-R parasite membranes displayed a higher content of short alkyl chain fatty acids, suggesting a partial inactivation of the fatty acid elongation enzyme system in HePC-R parasites. Sterol biosynthesis was found to be modified in HePC-R parasites, since the 24-alkylated sterol content was halved in HePC-R parasites; however, this modification was not related to HePC sensitivity. In conclusion, HePC resistance affects three lipid biochemical pathways: fatty acid elongation, the desaturase system responsible for fatty acid alkyl chain unsaturation, and the C-24-alkylation of sterols.

Effect of ketoconazole on lethal action of amphotericin B on Leishmania mexicana promastigotes.

The effect of ergosterol depletion by ketoconazole on the leishmanicidal activity of the pore-forming antibiotic amphotericin B (AmB) was investigated. Leishmania mexicana promastigotes were lysed within minutes by the addition of micromolar concentrations of AmB (0.5 microM) but became insensitive to AmB after growth in the presence of ketoconazole (0.25 microM, 90 h). Lipid chromatographic analysis indicated that under such conditions, ketoconazole depleted the major Leishmania sterols, dehydroepisterol and ergosterol. Plasma membrane vesicles prepared from ketoconazole-treated promastigotes exhibited a much reduced enhancement of their salt permeability after the addition of AmB at concentrations as high as 5 microM. This finding clearly indicates that upon ketoconazole treatment, the capacity of pore formation by the antibiotic is substantially impaired. The reduction of desmethyl sterols by ketoconazole was accompanied by a significant increase of 14-alpha-methyl sterols, but exogenous cholesterol remained unchanged. This ability of Leishmania promastigotes to incorporate cholesterol from the external medium may explain why ketoconazole-treated cells exhibited a much decreased but significative response to AmB when they were exposed to high AmB concentrations (2.5 or 5.0 microM). Parallel measurements by using a fluorescence energy transfer method indicated that binding of AmB to ketoconazole-treated Leishmania promastigotes and heat-transformed leishmanias was also decreased but to different extents, a finding that may be related to the differences in their sterol content. The results obtained clearly indicate that the specific interaction of AmB with desmethyl sterols, such as dehydroepisterol, ergosterol, and even exogenous cholesterol, is an absolute requirement for the lethal action exerted by this polyene antibiotic on L. mexicana promastigotes.

Inhibiting cholesterol synthesis reduces the binding and toxicity of amphotericin B against rabbit renal tubular cells in primary culture.

Renal tubular cells are a target of amphotericin B (AmB) toxicity, but the mechanisms involved in the tubular cell-AmB interactions are unknown. Ketoconazole was selected to lower the cholesterol content of rabbit renal tubular cells in primary culture. The consequences of cholesterol depletion on AmB nephrotoxicity was investigated in vitro as the inhibition of Na(+)-dependent phosphate uptake. After 1 h of exposure, AmB decreased phosphate uptake (49%, 77%, and 82% inhibition with 5, 10, and 20 microM of AmB, respectively). Pretreatment of cells with ketoconazole (10 microM for 24 h) reduced by 50% (P less than .01) the phosphate uptake inhibition induced by AmB, decreased cellular cholesterol synthesis (greater than 80% inhibition), and decreased AmB binding to cell membrane by 50%, as measured by the fluorescence extinction of a probe bound to tubular cell membrane. Incubation with exogenous exchangeable cholesterol again increased AmB binding to plasma membrane and restored AmB toxicity. These results demonstrate that the first step of AmB renal tubular toxicity is mediated by cellular cholesterol content and is parallel to the binding of AmB to cell membrane.

Orientation of anthracyclines in lipid monolayers and planar asymmetrical bilayers: a surface-enhanced resonance Raman scattering study.

The interaction of anthracyclines (daunorubicin and idarubicin) with monolayers of zwitterionic palmitoyloleoylphosphatidylcholine (POPC) and anionic dipalmitoylphosphatidic acid (POPC-DPPA 80-20 mol%) was studied by surface pressure measurements and compared with previous results obtained with other anthracyclines (pirarubicin and adriamycin). These anthracycline/phospholipid monolayers were next transferred by a Langmuir-Blodgett technique onto planar supports and studied by surface-enhanced resonance Raman scattering (SERRS), which gave information about the orientation of anthracycline in the monolayers. On the whole, the adsorption of anthracyclines in zwitterionic monolayers increases with the anthracycline hydrophobic/hydrophilic balance, which underlines the role of the hydrophobic component of the interaction. On the contrary, the anthracyclines remain adsorbed on the polar headgroups of the phospholipids in the presence of DPPA and form a screen that limits a deeper penetration of other anthracycline molecules. To study by SERRS measurements the crossing of pirarubicin through a phospholipid bilayer used as a membrane model, asymmetrical POPC-DPPA/POPC or POPC/POPC-DPPA bilayers were transferred by the Langmuir-Schäfer method, thanks to a laboratory-built set-up, and put in contact with a pirarubicin aqueous solution. It has been shown that the presence of anionic DPPA in the first monolayer in contact with pirarubicin would limit its crossing. This limiting effet is not observed if the first monolayer is zwitterionic.